Augmented Sparsifiers for Generalized Hypergraph Cuts with Applications to Decomposable Submodular Function Minimization

Abstract

In recent years, hypergraph generalizations of many graph cut problems have been introduced and analyzed as a way to better explore and understand complex systems and datasets characterized by multiway relationships. Recent work has made use of a generalized hypergraph cut function which for a hypergraph H = (V,E) can be defined by associating each hyperedge e ∈ E with a splitting function we, which assigns a penalty to each way of separating the nodes of e. When each we is a submodular cardinality-based splitting function, meaning that we(S) = g(|S|) for some concave function g, previous work has shown that a generalized hypergraph cut problem can be reduced to a directed graph cut problem on an augmented node set. However, existing reduction procedures often result in a dense graph, even when the hypergraph is sparse, which leads to slow runtimes for algorithms that run on the reduced graph. We introduce a new framework of sparsifying hypergraph-to-graph reductions, where a hypergraph cut defined by submodular cardinality-based splitting functions is (1+)-approximated by a cut on a directed graph. Our techniques are based on approximating concave functions using piecewise linear curves. For > 0 we need at most O(-1|e| |e|) edges to reduce any hyperedge e, which leads to faster runtimes for approximating generalized hypergraph s-t cut problems. For the machine learning heuristic of a clique splitting function, our approach requires only O(|e| -1/2 1) edges. This sparsification leads to faster approximate min s-t graph cut algorithms for certain classes of co-occurrence graphs. Finally, we apply our sparsification techniques to develop approximation algorithms for minimizing sums of cardinality-based submodular functions.